DE10196458T5 - Downstream airflow conditioning device for a disc drive with a ribbed stripper jacket - Google Patents

Abstract

An airflow conditioning device for a data storage device for weakening the aerodynamic excitation of air currents on device components, the data storage device having a housing that supports a rotating data storage disk and an actuator that are operatively interchanged in a data transfer relationship, and wherein the device includes an airflow Stripper comprising a wing that is mountable downstream of the actuator with respect to the direction of the air currents generated by the rotating plate and that extends substantially radially from an outer radial portion to an inner radial portion of the plate.

Description

Reference to related Registrations

This application claims the benefits based on U.S. Provisional Application Number 60/220 722 dated July 26, 2000.

Field of the Invention

This invention relates generally in the field of data storage devices and in particular, but not restrictive, on the control of aerodynamic excitation caused by air currents which generated by the rotating data storage disks Transfer components becomes.

Background of the Invention

Modern data storage devices such as disk drives are commonly used in a variety of computer environments used to store large amounts of data in one form save that for easily available to a user is. Generally, a disk drive has a magnetic disk or two or more stacked one on top of the other Magnetic disks on by a high speed motor be rotated. Each disk has a data storage surface that divided into a series of generally concentric data tracks on which data is stored in the form of magnetic flux transitions.

A data transmission element such as Example a magnetic transducer is activated by an actuator or actuator to selected Positions on the data storage surface moved to the magnetic flux transitions at Reading data from disk and sampling while writing transmit electrical signals from data to the disk to induce magnetic flux transitions. The active elements of the data transmission element are through suspension structures worn, which extend from the actuator. The active ones Elements appear at a short distance above the data storage surface an air bearing held by the rotating plates caused air flows is produced.

There is an ongoing trend in industry increasing data storage capacity and processing speed, while the physical size of the disk drive is maintained or reduced. As a result, the data transmission element and the mounting structures continuously shrinked, and data storage densities are continuously increased. The result is an overall increased sensitivity to vibration in relation to to the track width. These vibrations can have an adverse effect on the positioning control systems that have the actuator relative move to the rotating plates.

A source of arousal that no longer ignore can be left stirring from those within the disk stack and onto the disk drive components impinging air currents. The air flow velocity and consequently the associated one personnel increase in relation to the radial distance from the axis of rotation. So move the air flows on outer sections of the plates are faster and are more likely to be turbulent. Turbulence can cause adverse vibrations or aerodynamic excitement on the plates (flutter - "flutter") and / or the actuator, especially the suspension elements (Shaking - "buffeting") transmitted. Turbulence can also be generated by vertebral detachment (so-called "shedding vortices") by the vortex wake or the post-flow of the actuator is formed when the air flow flows past the actuator, and which also on the plate edges acts when the air flows ejected from the stack of plates become. Further increases a post-flow excitation (wake excitation) from the actuator the plate vibration.

It has been found that an airflow excitation by an airflow conditioning device can be reduced using an airflow stripper or wiper and includes an air dam downstream of the actuator. The embodiments the present invention is directed to this improvement.

Outline of the invention

Embodiments of the Present Invention are based on providing an airflow conditioning device for a Disk drive to weaken aerodynamic excitation of air flows on disk drive components directed. The disk drive typically has a housing which is a rotating data storage disk and an actuator that functionally in one Data transfer relation cooperates, holds. In one embodiment of the present Invention includes the airflow conditioning device is an airflow stripper or an airflow wiping device which is located downstream of the actuator Regarding the direction of the air flows can be held. The Airflow stripper includes a wing that is essentially radially from an outer radial section to an inner radial portion of the data storage disk and adjacent to the data storage surface extends. The wing is substantially transverse to the distal end of the actuator the radial path of actuator movement over the Data storage disk arranged.

In a further embodiment of the invention, the airflow conditioning device comprises a frame which can be held by the housing and which in turn holds the airflow stripper tert. The frame may also have a shroud that forms a peripheral surface that is substantially transverse to the outer edge of the data storage disk and intersects the airflow stripper. The shroud may further comprise a fin which forms a planar surface which extends from the peripheral surface and in substantially the same direction with the data storage surface of the data disk.

According to a further embodiment In the present invention, the frame supports the airflow stripper when moving between an operating position and a retracted position Position moved. A retention element holds that Airflow stripper in the operating position. A preload element can by pressure with the housing are engaged to provide a fastening force to the frame Holding it in the housing too produce.

These and various other features as well Advantages that characterize the present invention go out the present detailed description with reference to FIG the attached Drawing.

Brief descriptions of the drawing

Show it:

1 1 shows a schematic top view of a disk drive which is constructed in accordance with an embodiment of the present invention, the cover being partially cut away,

2 an enlarged detail view of the airflow stripper of 1 .

3 a view similar to that 2 illustrating an airflow stripper constructed in accordance with an alternative embodiment of the present invention,

4 a partial sectional view taken along line 4-4 in 1 which shows the airflow stripper downstream of the read / write heads and nested with the plates,

5 an elevation view of the airflow stripper of FIG 1 which is rotatably supported by the base deck,

6 an isometric view of the disk drive of 1 the plate and actuator being partially cut away to show the airflow stripper in the retracted position; the airflow stripper is also shown with broken lines in the operating position,

7 and 8th simplified top view of the disk drive from 1 which represent in more detail the shroud formed by the base deck,

9 an enlarged detail view of a portion of the air flow conditioning device from the disk drive of 1 .

10 1 shows a schematic elevation of a data storage disk for the representation of vertebral detachments (shedding vortices) from the ejected air currents which act on the disk edge,

11 1 shows a schematic elevation of a data storage disk and a casing, which are constructed in accordance with the present invention, to illustrate eddy separations from the ejected air currents which act on the disk edge,

12 a sectional view taken along line 12-12 of 6 to show the airflow stripper in the retracted position,

13 to 15 schematic representations of an assembly sequence for the disk drive of 1 , connecting the actuator to the stack of plates ( 13 ) the airflow conditioning device is placed on the housing with the airflow stripper retracted ( 14 ), and the airflow stripper operatively extends to the plate stack and is nested with it ( 15 )

16 1 shows a schematic top view of the airflow stripper which is positioned and held in the operating position,

17 an elevation of the frame portion of the airflow conditioning device of FIG 1 , and

18 a sectional view taken along section line 18-18 in 17 ,

detailed description

It will now refer to the drawings in general and in particular 1 received in a top view of a disk drive 100 is shown, which is constructed according to an embodiment of the present invention. The disk drive 100 includes a base 102 with various drive components attached, and a cover 104 (partially cut away) together with the base 102 and a peripheral seal 105 forms a housing that provides a sealed internal environment for the disk drive 100 provides. Numerous structural details are not included in the following description, since they are well known to the person skilled in the art and are not necessary for an understanding of the present invention.

At the base 102 is an engine 106 attached to which one or more plate (s) 108 stacked for rotation at high speed and by a clamping ring 110 are set. If multiple plates 108 are stacked one on top of the other to form a stack of plates are adjacent plates 108 typically separated by a plate spacer (not shown). An actuator or actuator 112 swivels around a swivel bearing 115 in one to the plates 108 parallel plane. The actuator 112 has actuator arms 116 on (in 1 only one is shown), which load arms 118 moving across the plat th 108 hold when the actuator arms 116 themselves within the spaces between adjacent panels 108 move. The load arms 118 are flex elements, the data transmission elements, such as read / write heads 120 wear, with each of the read / write heads 120 functionally an interface with a surface of one of the plates 108 in a data reading and writing relationship. This relationship is maintained by a slider (not shown) which holds the read / write head 120 functionally on an air bearing that carries through from the rotating plates 108 generated air flows is maintained.

Each of the plates 108 has a data storage area with a data recording surface 122 on, which is divided into concentric circular data tracks (not shown). Each of the read / write heads 120 is positioned adjacent to a desired data track to read or write data from the data track. The data recording surface 122 can inside by a circular landing zone 124 be limited to the read / write heads 120 against the plates in question 108 come to rest when the plates 108 do not turn. Alternatively, the landing zone can be located elsewhere.

The actuator 112 is powered by a voice coil motor or voice coil motor (VCM) 128 positioned by an electrical coil 130 and has a magnetic circuit source. The magnetic circuit source conventionally includes one or more magnets that are carried by magnetic poles to complete the magnetic circuit. If a controlled current through the actuator coil 130 is sent, an electromagnetic field is created that interacts with the magnetic circuit and causes the actuator coil to move 130 emotional. If the actuator coil 130 moves, the actuator restricts 112 around the pivot bearing 115 and causes the read / write heads 120 over the plates 108 move.

As already mentioned, the engine turns 106 the plates 108 at high speed when the read / write head 120 Data from the data storage surface 122 reads or writes to them. The kinetic energy of the rotating plates 108 transfers through the boundary layer at the plate / air interface, which induces a torque component on air flows, and the centrifugal force imparts a radial force component to the air flows, so that a generally outward spiraling air flow is generated. The air currents gain during the radial outward movement because of the relatively higher linear speed of the plate 108 with increasing radial distance from the axis of rotation at speed.

An airflow conditioning device 138 includes an airflow stripper 140 , the downstream of the actuator 112 in terms of the direction of the currents ( 1 , Reference number 111 ) can be held. The airflow stripper 140 includes a number of wings 142 (of which only one in 1 is shown) which extends substantially radially from an outer radial section to an inner radial section of the data plate 108 extend, and thereby adjacent to the data storage surface 122 the plate 108 are arranged. If two or more plates 108 the airflow stripper can be stacked or stacked with spacers and form a stack of plates 140 a corresponding number of wings 142 have in the spaces between adjacent plates 108 are arranged to face both data storage surfaces 122 contiguous plates 108 are neighboring.

2 is an enlarged detail view of the airflow stripper 140 of 1 to represent the way in which the wing 142 functionally substantially transverse to the distal end of the actuator 112 is arranged. The wing shows in detail 142 preferably a leading edge 144 with a characteristic arch shape, which follows the arcuate radial path of the read / write head 120 over the plate 108 is adjusted. This enables an essentially constant spacing of the wing 142 downstream of the read / write head 120 in all positions of the actuator 112 ,

Although a constant distance is preferable 3 one of the 2 Similar view to illustrate an alternative wing 142 with a substantially linear leading edge 144 , In this case the minimum distance between the wings is 142 and the read / write head 120 preferably at the outermost portion of the data storage surface 122 where the speed of the air flow is greatest.

4 FIG. 4 is a sectional view taken along section line 4-4 in FIG 1 to represent the several wings 142 with the stacked plates 108 of the plate stack are nested. Every wing 142 is dimensioned so that it space between adjacent panels 108 essentially fills. 4 illustrates a plate stack with two plates 108 However, it is understood that a stack of plates with more or fewer plates 108 also from a corresponding number of wings 142 can be dealt with.

By the wings 142 essentially the spaces downstream of the read / write heads 120 fill in, they reduce the aerodynamic excitation effects of the air flows on the actuator 112 , For example, the wings decrease 142 the Reynold's shear loads on the actuator 112 act by retarding the air current mean flow. The wings 142 also act like a flow straightener, essentially like a honeycomb device device to create fully developed airflow flow conditions, reducing the downstream of the actuator 112 formed three-dimensional post-flow is suppressed. Because the aerodynamic excitation on the actuator 112 For example, for the above reasons, the torque disturbance influences on the desired movement of the actuator 112 reduced.

The airflow stripper 140 can generally be carried by the housing. Illustrated for example 5 an elevation view of the airflow stripper 140 of 1 with one axis 146 , of which the several wings 142 depart. The axis 146 can be provided with a longitudinal opening, which with a shoulder or a hub 148 engagingly engaging through a portion of the base 102 supported or formed thereby. A tool feature 149 can be provided with an assembly tool for rotating the axis 146 engaging to engage.

This bracket arrangement or equivalent can also be used to support a swivel bearing of the airflow stripper 140 provide so that the wing 142 between a retracted position (not with the plates 108 nested) and an operating position (with the plates 108 nested) can be moved. 1 illustrates the operating position of the airflow stripper 140 , 6 Figure 3 is a partially cut-away isometric view of the disk drive 100 of 1 to represent the airflow stripper rotated to the retracted position 140 and to illustrate the operating position of the airflow stripper 140 in broken lines.

The airflow stripper 140 can be more effective when wrapped around the plate with a shroud 108 and downstream of the actuator 112 is used. The term "shroud" as used herein means a stationary upstanding surface across the edges of the rotating plates 108 , Wrapping or cladding the stack of plates can reduce sources of aerodynamic excitation. The sheathing also creates a layered flow and reduces three-dimensional effects in the housing. The sheathing or cladding also minimizes the effects of eddy detachments at the edges of the plate, and the axial forces on the plate 108 of the air streams expelled from the stack of plates. Wrapping or cladding also reduces the resistance (resistive drag) on the rotating plates 108 , which minimizes the energy required to maintain the stack of disks at a desired rotational speed.

In order to minimize the number of parts and to simplify manufacturing processes, it can be advantageous to have a casing or cladding as part of the base 102 provided. Ideally, it would have the basis 102 A characteristic protruding section (s) that define the circumference of the rotating plates 108 completely surrounded / surrounded. For the actuator 112 however, an opening in the jacket is required. The opening is at least wide enough to provide clearance for a middle section of the actuator 112 when the read / write heads move 120 to be provided within the desired movement limits.

7 and 8th are simplified views of a portion of the disk drive 100 of 1 which is from the base deck 102 represent formed sheath extending circumferentially from a first end 150 to a second end 152 extends and an opening 154 releases through which the actuator 112 emotional. In 7 is the actuator 112 pivoted to the desired inner movement limit at which the read / write head 120 in the landing zone 124 can land. In 8th is the actuator 112 pivoted to the desired outer movement limit at which the actuator 112 and the stack of disks are not demerged. This enables the actuator to be installed or replaced 112 or the stack of plates while the counterpart remains installed. This also enables the use of parking devices (not shown) for the read / write head 120 , such as unloading ramps that the read / write heads 120 Hold away from the stack of plates for improved shock protection at rest.

If like the disk drive 100 of 1 the operative outer movement limit of the actuator 112 is an outermost data track, the portion of the plate stack may be downstream of the actuator 112 to be encased after the actuator 112 and the plate stack are connected to one another. Accordingly, the airflow conditioning device includes 138 of 1 a mounting frame section 156 which has a casing section with a substantially transverse to the outer edge of the plate 108 arranged peripheral surface 158 carries or holds. The peripheral area 158 extends from a first end to the wing 142 of the airflow stripper 140 cuts to a second end around the opening 154 to narrow ( 7 and 8th ) through which the actuator 112 moves, whereby preferably the plates 108 be encased or clad as much as possible.

9 Fig. 3 is an enlarged detail view of part of the portion of the peripheral surface 158 the airflow conditioning device 138 , By applying the circumferential surface closely 158 at the edge or edge of the plate 108 at its first end adjacent to the airflow stripper 140 there is essentially no air from the disk stack in the area of the read / write head 120 be expelled. By sloping or chamfering the peripheral surface 158 away from the edge of the plate 108 at the second end and in between, proporti onal more air flow from the stack of plates into that of the read / write head 120 ejected remote area. This results in a channeling of air flows from the plate stack in one by the arrow 161 indicated direction are expelled.

But if the gap or space between the peripheral surface 158 and the edge of the plate 108 increases, which leads to relatively more air flows ejected from the plate stack, the coupling of air flows from neighboring rooms is greater and results in turbulence. 10 illustrates the manner in which the radially ejected air streams eject circular eddy currents from turbulent air flows onto the edge of the plate 108 Apply axial forces. This turbulence is caused by vortices detached from the plate edges. In order to minimize the effects of detaching vertebrae, the. Air stream conditioner 138 ( 1 ) a rib or fin 160 in planar alignment with each of the plates 108 exhibit. 11 puts the rib 160 with opposite planar surfaces 162 . 164 that are essentially in the same direction as the data storage surfaces 122 the plate in question 108 are aligned. A transverse edge 166 is in a close relationship with the edge of the plate 108 arranged. The air flows expelled are as shown by the reference arrows in 11 is indicated from the plate 108 distracted to reduce the effects of peeling vertebrae. This reduces the aerodynamic excitation effects of the air flows on the plates 108 ,

12 Fig. 12 is a sectional view taken along the line 12-12 in 6 that represents how the wings 142 with the ribs 160 in the retracted position of the airflow stripper 140 can be nested or interlocked. This enables the airflow conditioning device 138 install inside the case and the airflow stripper 140 then move to the operating position.

13 to 15 are top views showing an assembly sequence related to the retractability of the airflow stripper 140 , First, the actuator 112 and the stack of plates at the base 102 attached and nested ( 13 ). Alternatively, the actuator 112 and the stack of panels nested and together on the base deck 102 be installed. Then the air flow conditioning device 138 at the base 102 with the airflow stripper 140 positioned in the retracted position ( 14 ). The airflow stripper 140 is then moved to the operating position ( 15 ).

A number of design features for (better) manufacturability can be provided. For example, features that generally include the airflow stripper can be provided 140 position positively in the operating position. 16 is an enlarged view of the airflow stripper 140 , the wing 142 an expanded section 168 which includes an attachment to a selected section of the base 102 stands to limit another rotation after reaching the operating position.

Another design feature for easier manufacturability ensures that the airflow stripper is held on positively 140 in the operating position. In 16 includes, for example, the airflow conditioning device 138 an extended spring element 170 , which has a recess formed therein 172 having. The axis 146 involves an approach 174 by recording in the recess 172 engages with it. Rotation of the airflow stripper to the operating position causes the neck section 174 with the spring section 170 comes into engagement and deflects it. In the operating position, the approach 174 in the recess 172 recorded and held when the spring section 170 moved back to against the approach 174 to press on.

16 also illustrates an alternative way of holding the airflow stripper 140 with a swivel movement. The mounting frame section 156 can, for example, an extending mounting element 176 have an opening (not shown) in which the axis 146 is included for rotation.

Another design feature for easier manufacturability is securing or fastening the section of the fastening frame 156 the airflow conditioning device 138 ready in the housing without the need for separate fasteners such as threaded fasteners. 17 shows a partial sectional view of the mounting frame 156 in the way in which he operates between the base 102 and the cover 104 can be inserted. The mounting frame 156 can with one or more positioning approaches 178 at one of its ends and one or more positioning lugs 180 be provided at the other of its ends with corresponding openings in the base 102 in the operating position of the mounting frame 156 are aligned. A self-supporting spring element 182 has an expanded section 184 on that in pressure engagement with the cover 104 comes when this is at the base 102 is attached. This sets the spring element 182 a force exerted on the mounting frame 156 is transmitted, causing the mounting frame 156 against the base 102 is pushed or pressed. This interaction of the spring 182 and the approaches 178 . 180 provides the necessary fastening force on the fastening frame 156 ready without the need for separate fasteners.

18 is a sectional view along the line 18-18 from 17 to represent one of the mounting frame 156 formed cavity 186 holding a filter cartridge 188 can take and hold.

In an alternative embodiment, the wing 142 ( 1 ) radially from that in 1 shown termination point are extended so that the distal end in the operating position extends adjacent to the innermost data track, so as to relatively increase the air funnel effect of the airflow conditioning device. In another alternative embodiment, the airflow conditioning device in combination with a disk drive with a spindle motor rotation can be opposite to that in FIG 1 can be used, wherein the airflow conditioning device is effectively upstream of the actuator 112 and in particular upstream of the read / write head 120 located. In summary, an airflow conditioning device for a data storage system (for example 100 ) for weakening the aerodynamic excitation effects of air flows within a data stack of data disks (e.g. 108 ) that are under the control of an engine (for example 106 ) rotate, generated. The data plates rotate in functional exchange with an actuator (for example 112 ) that has a read / write arrangement (for example 120 ) in a data reading and writing relationship.

The airflow conditioning device may include a downstream stripper (for example 140 ) with a number of wings (for example 142 ) assigned to each of the number of plates and inserted between adjacent plates. Preferably, the wings are arranged substantially transversely to the path of the read / write head, which extends radially across the data plate from an outer radial section to an inner radial section of the plate.

The airflow conditioner may more finely have a downstream ribbed shroud (for example 138 ), which makes the air flow layered and reduces aerodynamic excitation of the plates and the actuator arrangement. The sheath can be a number of fins (for example 160 ) that extend in substantially the same direction or extent as the plates and in a closely-fitting edge-to-edge relationship to direct the expelled air streams from the stack of plates without mixing air currents from the spaces between adjacent plates.

The airflow conditioning device may further include a frame (for example 156 ), which by a housing (for example 102 ) of the data storage system can be held and in turn holds the airflow stripper. The frame can be a casing or cladding (for example 158 ), which defines a circumferential surface substantially transversely to the outer edge of the data storage plate and the ribs or fins and intersects the airflow stripper. The frame can be holding means (for example 148 . 176 ) for holding the airflow stripper in its movement between an operating position and a retracted position, as well as restraining means (for example 170 . 174 ) for operationally holding the airflow stripper in the operating position.

The frame can be a preload element (for example 182 ) have, which can be brought into pressure engagement with the housing and provides a fastening force on the frame within the housing.

It should be noted that there are numerous Features and advantages of various embodiments of the present Invention in the foregoing description along with details of Structure and function of various embodiments of the invention It has been demonstrated that this disclosure is illustrative only serves and that changes in detail, especially with regard to the structure of the arrangement of parts within the principles of the present invention in the full extent of the broad general meaning the terms in which the appended claims are expressed can. For example, the size and the Arrangement of the airflow conditioner vary as they are maintains essentially the same functionality without sacrificing scope and Depart from the spirit of the present invention. Furthermore Although the preferred embodiment described here is a downstream stripper arrangement for a disk drive arrangement directed, however, it should be noted that experts follow the teachings of present invention can also be applied to other systems, such as for example data storage test or certification systems, servo track recorders or optical data storage systems without sacrificing scope and spirit depart from the present invention.

Summary

downstream AIRFLOW CONDITIONING DEVICE FOR A DISC DRIVE WITH RIBBED STRIPPER-WRAPPING

Airflow conditioning device ( 138 ) for a data storage device ( 100 ) which is a rotating data storage disk ( 108 ) and an actuator ( 112 ) used in an operational exchange in a data reading and writing relationship. The device ( 138 ) includes an airflow stripper ( 140 ) downstream of the actuator ( 112 ) in terms of the direction of the spinning Plates ( 108 ) generated air flows. The airflow stripper ( 140 ) includes a wing ( 142 ) which extends essentially radially from an outer radial section to an inner radial section of the data storage disk ( 108 ) and adjacent to the data storage surface ( 122 ) extends. The wing ( 142 ) is essentially transverse to the distal end ( 120 ) of the actuator ( 12 ) along the radial trajectory of the actuator ( 112 ) via the data plate ( 108 ) arranged.

Claims (10)

Airflow conditioning device for a data storage device to weaken aerodynamic excitation of air flows on device components, wherein the data storage device includes a housing that has a rotating Data storage disk and an actuator in a data transfer relationship functionally in exchange stand, supports, and wherein the device is an airflow stripper has a wing includes the downstream of the actuator with respect to the direction of that produced by the rotating plate airflows can be held essentially radially from an outer radial section extends to an inner radial portion of the plate. The device of claim 1, wherein the wing is substantially is arranged transversely to a distal end of the actuator. The device of claim 1, further comprising a frame, that of the housing can be held, and which in turn holds the airflow stripper, wherein the frame has a casing or covering that a peripheral surface essentially transversely to the outer edge of the data storage disk and the wing cuts. The device of claim 3, wherein the casing includes a fin or fin that defines a planar surface, which differs from the peripheral surface and essentially in the same direction as the data storage disk extends, and further an edge substantially transversely the planar surface and in close association parallel to the outer edge of the data plate. The apparatus of claim 3, wherein the frame the wing when moving between an operating position and a retracted position Holds position, and wherein the frame comprises a retaining element, the the wing holds in the operating position. The device of claim 3, wherein the frame is a by pressure with the housing engageable biasing member having a fastening force on the frame inside the case exercises. Disk drive with: a housing with a base and a cover, one by one at the base supported motor turned plate stack, one through the Base-mounted actuator with a distal end that is a data transmission element in a Data transfer relation with a data storage surface of the data stack moves, and one held by the housing Airflow conditioning device using an airflow stripper downstream of the actuator with respect to the direction of through the rotating plate stack generated air flows includes. The disk drive of claim 7, wherein the airflow stripper a wing which is substantially radial from an outer radial portion to an inner radial portion of the plate stack and adjacent to the data storage surface extends and is positioned substantially across the distal end of the actuator is. The disk drive of claim 7, wherein the airflow conditioning device has a shroud that is essentially one transversely to the outer edge of the plate stack extending and intersecting the wing defining peripheral surface. The disk drive of claim 9, wherein the casing has a rib or fin that extends substantially from the peripheral surface extends parallel to the plate stack.